DE2346630A1 - METHOD AND DEVICE FOR SPRAYING A MULTI-COMPONENT MATERIAL - Google Patents

Description

Dr. E Wfegsntf. D!? R.> Fn ^. W. NIemanit * "' ^ί0 '

Dr. M. Kolilsr. Oipf.-fag. c. Gsrnftardl

Patent attorneys

Hamburg 50 - Königstrasse 28

W.26037 / 73 20 / Hh

Kansburg Corp.

Indianapolis, Indiana (V.St.A.)

Method and device for spraying a multi-component material.

The invention relates to a method and an apparatus for spraying a multi-component material. The application of the method and the device according to the invention to a multi-member provided with a catalyst component material reduces the pollution of the atmosphere with solvent vapors, the flowable paints or colored liquids are assigned, and eliminates or reduces the treatment or heat treatment of the objects coated with the spray at elevated Temperatures for long periods of time. In accordance with the invention, an article having a uniform and substantially continuous film can be from about 0.03 to about 0.05 mm (1 to 2 mils) thick using multi-component materials be provided, which are mixed immediately before their atomization.

A098U / 0421

The assembly line manufacturing of automobiles, refrigerators, sewing machines, bicycles, and others mass-produced Objects has generally focused on paint coating supported by spraying in order to give these objects an even, smooth decorative and protective coating or —To give the finish these require.

By about 1950 these were almost ubiquitous Tools for coating objects with a spray material an externally mixing compressed air spray gun and a high temperature oven. Color, a mixture of pigments and resins ^ those in a volatile, flowable carrier material (usually a hydrocarbon solvent) is taken to an all-metal spray gun a pressure of a few psi (1 psi corresponds to approximately 0.07 kp / cm) and through a narrow cylindrical The opening on the front part of the pistol was pushed out. This narrow, cylindrical stream of paint becomes immediate then struck by a jet of air which, under a pressure of about 0.7 to about 7 kp / cm (OK to 100 psi) stands. The compressed air is fed to the spray gun through a separate delivery line and exits the gun an annular opening surrounding the colorant opening, and also from a number of adjacent air openings out. The compressed air jets or streams atomize the flowable paint emerging from the paint orifice, to a spray of more or less uniform small drops and form the spray mist or the atomized material, which consists of droplets, into an elliptical or fan-shaped spray jet or the like. To what, according to the forward speed of the compressed air is advanced in the direction of the objects to be painted and on these Objects is deposited. By manual operation or by automatic operation of the spray gun, a relatively smooth and even and essentially continuous flowable paint film on or over

4098U / CU21

the curses generated by the objects when the objects be promoted through the coating area.

The freshly painted objects are moved by the conveyor a short distance beyond the spray area to an oven. The distance from the spray area to the oven is referred to as the so-called flash-off area, where part of the solvent in the flowable paint film evaporates into the atmosphere. The conveyor then moves the objects into a furnace inside, v / o brought inked objects to a temperature in the range between about 177 ° C and about 260 ° C (35O ⁰ F to 500 ⁰ F) or even more for a period of time which is in the range of 10 to 30 minutes or more. Ilitzhardening of the paint is necessary so that the remaining part of the solvent in the paint film evaporates and in order to promote or accelerate chemical changes, so as to provide the surface of the objects with a hard, smooth and essentially continuous, good-looking dry paint film to pass.

Although the combination of spray paint coating and treatment at high temperatures makes an attractive one and produces the desired paint film, has the known paint spray gun a number of serious disadvantages. A remarkable number of the paint droplets will pass through on the objects the compressed air is driven past and wasted as so-called overspray. To eliminate the spray problem are expensive filters and other equipment to clean the excess material is necessary. Evaporation of the solvents into the atmosphere not only leads to a health hazard for the painters but also contributes also contributes significantly to atmospheric pollution. They also bear the elevated temperatures required in the furnace in order to treat or cure the flowable paint, are noteworthy at the cost of paint spraying,

4098U7CU21

and they consume large amounts of natural gas or others scarce energy sources. Accordingly, the oven with its carefully crafted facilities is based around the oven Maintaining precise temperatures, expensive to manufacture and maintain. The ovens "also occupy a considerable amount of space of the factory floor, and the objects, while they move continuously on the conveyor for periods of time from 10 to 30 minutes or more.

Starting in the 1950s, four successive technical advances affected the situation of the externally mixing compressed air spray gun during industrial painting. These advances are electrostatic Spray coating, airless spray coating, electrophoretic coating, and powder spray coating.

In electrostatic spray coating, an electrostatic charge is applied to the paint particles so that the Charged particles are attracted by electrostatic forces in the direction of the objects and deposited on them. While the original form of electrostatic painting, Randsburg Method No. 1, retained the Ketall air spray gun, eliminated subsequent ones Electrostatic spray coating embodiments include the metal air spray gun. The electrostatic Spray coating significantly reduced the amount of overspray, resulting in overspray economic savings. Furthermore, the reduction in excess material sprayed decreased which was part of the electrostatic spray coating, the health ones The hazards and expense of excess material collecting facilities that was required.

In a corresponding manner, the excess sprayed material was also coated by the airless spray paint decreased. By applying the paint under high pressure of a few hundred psi through the small opening of a specially designed If the nozzle is pushed through, the paint will turn into a

4098 H / 042 1

Spray mist or the like. Of sufficient size, of sufficient quality and with sufficient conveyor speed for industrial paint spray coating atomized. The airless spray paint coating eliminated the paint wasting blowout of compressed air.

Electrophoretic dye coating is needed at all no more spray gun. Objects to be painted are brought into a large bathroom on a conveyor. and passed through this, which resin coating material particles contains j those flowable in a liquid or something Medium are suspended. While the objects are immersed in the bath, an electric field is created between the objects and an electrode grid in the tank, or the tank itself serves as an electrode. The electric Field causes particles of resin coating material to move towards the objects and onto the surface of the objects to a thin film of resin coating material to form on the object.

The known air spray gun also no longer needs powder paint coating. The powder is dry, whereby finely ground particles or particles having a particle size of up to about 200 ^ i in diameter. The powder is introduced into an air stream, initiated in this and supplied from a fluidized powder container to an electrostatic powder spray gun which has the gives individual powder particles a high electrostatic charge. The powder particles are on an object that is at a potential that attracts a particle, due to the effect of the electrostatic forces and the surrounding forces Air deposed or knocked down. The powder particles form a coating that sticks or adheres to the object surface due to the electrostatic forces, the deposited charged particles and the potential that attracts a particle or particle Subject are assigned.

4098U / CU21

Neither the electrostatic spray paint coating nor the pressurized paint spray coating, nor the electrostatic one Powder paint coating or electrophoretic paint coating eliminates the bulky, expensive high temperature oven necessary to make an acceptable smooth and iia essential uniform, decorative and to create a protective coating or finish.

In accordance with the invention there is provided a method and apparatus for providing an article with a smooth, substantially continuous decorative and protective finish, reducing environmental pollution and either reducing the need to provide an oven to treat the coating or finish or to cure, is eliminated or the length of time during which the coated article is subjected to an elevated temperature is minimized. Before describing the method and the device according to the invention, an explanation of the quality requirements for coatings of industrial products will be given in order to enable a better understanding of the invention.

In order to adequately protect and decorate the surface of an article with a substantially continuous dry film of paint, the surface must be covered with a film about 0.03 to about 0.05 nua (1 to 2 mils) thick. Dry films of small thickness do not cover the imperfections of the material surface and do not have enough resistance to wear and damage, especially from impact. Dry films of greater thickness add unnecessarily to the cost of coating and are also often less resistant to chipping, scraping and cracking than thinner films.

To dry films without running off color material or color material gutters or unacceptable Oberflächenrauh- to form uniform, the spray gun should be the color in flowable

A098H / 0421

2348630

atomize due particles, the maximum size of which does not exceed a given diameter, and preferably most of the particles are of a smaller diameter. One method of determining whether atomization is appropriate in terms of particle size is to measure the diameter of spots or spots formed by spray particles striking an appropriate target under controlled conditions. The conditions that have been taken as a basis in practice relate to the passing of an approximately 10 approximately 15 cm (4 "χ 6") flat target by the spray jet or spray mist in the longitudinal direction along its longitudinal dimension, with the an area in a plane perpendicular to the spray axis at a distance of about 30 cni (12 ^M ) from the spray source is passed at sufficient speed that the area of the target exposed to the spray is substantially free of overlapping points. If the mean diameter of the ten largest spots on the target (hereinafter referred to as the spray spot size) is less than about 0.38 ran (15 mils), the spray is suitable for producing high quality finishes, although where less severe. Requirements are placed on the coating or the finish, sprayings that produce a spray point size of 0.5i 1 ³ Ki (20 mil) can be sufficient. When reference is made in the following to the spray point size of the spray particles, it is to be understood that the size mentioned is that size which has been determined under the conditions just mentioned.

Generally speaking, articles require two successive coats of paint. For example, get automobile bodies manufactured in the United States first apply a primer coat of relatively cheap rust-preventing materials. This coating is dried and sanded smooth, and then the vehicle is

A098U / 0A2

tool body finished with a solvent-acrylic based paint by overspraying. The finish coat is applied by conventional compressed air guns or by the newer electrostatic guns. The guns are held about 20 to about 30 cm (8 to 12 inches) from the vehicle body and spray several hundred to one thousand ecm of paint per minute. The guns shape the atomized paint particles into a pattern which is deposited on the vehicle body as an elongated elliptical pattern approximately 46 cm long and approximately 15 cm wide (18 6 inches) at its largest dimensions. Usually the paint as delivered to the gun has a viscosity of about 20 seconds, which is stated in a Ford No. 4 container is measured, and has 50 ⁰ Jo weight proportions. volatile hydrocarbon solvents, which eventually evaporate into the atmosphere during spraying, during so-called flash-off and during heating, drying or curing into the atmosphere. The remaining 50 ^c / o solid components consist essentially of acrylic resin and the necessary pigments and / or of metallic flakes, which give the final finish the desired color and glow. Although acrylic resins are widely used to coat vehicle bodies, other resins such as alkyd melamine and polyester resins can also be used to coat articles.

Most made in the United States Vehicle bodies move through the spray coating booth and subsequently through the oven at one speed of about 4.5 m / min. (15 ft / min). The spray paint coating takes about a minute per vehicle, however requires heating or curing approximately 25 minutes. The curing of acrylic paints requires temperatures in the

409 8 14/0421

Range of approximately 204 ° C (400 ° F).

Resin manufacturers are known to make resins by adding appropriate chemicals instead of can be converted into a solid film by curing at elevated temperatures. The transformation of a resin from a relatively stable flowable state to a very stable solid state usually requires the addition of a catalyst to the resin and is technically known as polymerization. Catalysts are Chemicals, the addition of which in relatively small proportions to the resin accelerates the polymerisation of the resin or promotes. Catalysts are widely used to facilitate the polymerization of resins necessary for thin Films are used to speed up, among other things because of their relatively long possible processing— time (pot life). Pot life, as this term is used, means the length of time within which a mixture is produced from resin and catalyst becomes unsprayable or can no longer be sprayed, because of the effect on the Viscosity caused by rapid polymerisation.

Accordingly, multi-components provided with a catalyst are ten materials for spraying objects with thin Film because of the difficulty of quickly and consistently mixing the ingredients, cleaning them up, or cleaning them up the mixing chamber at the end of the spraying and with the correct atomization of those provided with a catalyst Materials, especially during the beginning and the end of the spraying process, have not been used.

An embodiment of the method according to the invention for spraying a multicomponent material has the following stages: The introduction of the components of the material to be sprayed into a mixing chamber, the mixing the components in the chamber, the sending or dispensing of the mixed material from an opening in the chamber,

4098H / 0421

directing compressed air onto the material being dispensed from the orifice to convert the material being dispensed into a Spray from the material or the like. To transform that Cutting off or terminating the introduction of the components into the chamber without changing the position of the opening, to stop the spraying process of the material without deteriorating the quality of the sprayed material and immediately following the termination of the feeding of the Components in the chamber the removal of the remainder of the components from the chamber by means of a through the Chimney he passing compressed air flow.

The device according to the invention for spraying a meniscus material having a gun body; a first and second device to the gun body with separate sources of the first and second components to be mixed and sprayed onto the gun, connect to; means for connecting the gun body to a source of pressurized air; a facility for Directing a jet of compressed air out of the gun body and with a discharge opening for the multi-component material associated with the first and second means and with respect to the means for aligning of the compressed air flow out of the gun body is arranged interacting, un a spray or Like. To create the Hehrkoiaponentencaterials is marked by a mixing device for the first and the second component in the connection between the first and the second means of the body and the emission port; by a device for connecting the compressed air source with the mixing chamber; by a mixing device attached to the gun body from a first position in which the first and the second component can flow through the mixing device to the discharge opening, to one second position in which the flow of the first and the second component is blocked and a flow of compressed air

409814/0 * 21

- ii -

by the mixing device and. the broadcast opening can flow, is movably attached, wherein the mixing device is movably attached to the body in such a way that their movement does not open the outside opening for the wiped Components neither longitudinally along their axis nor laterally with respect to the device moved for guiding or directing the flow of compressed air, and by an actuator for moving the mixing device between the first and second positions,

The device according to the present invention has a plurality of compressed air nozzles or jets towards the multicomponent material being dispensed are aligned to atomize the material into a spray jet or mist of flowable particles, which have such a size and shape, uza on the Object to produce a quality finish. It is significant that the opening from which the teaching component material is output, not axially nor laterally with respect to the jets of compressed air to either Time moved during the atomization or during the cleaning of the Mehrkoiaponentenmaterials from the mixing chamber. In the event that this discharge opening moves axially or laterally out of its interacting position with the air currents moved out, the flowable material is not atomized into the desired particle size and the desired Spray pattern is not formed, which leads to large droplets and / or uneven distribution of the material, which results in the Quality of the finish on the item seriously deteriorated. It is also a significant feature of the present Invention that the compressed air flows continue during the cleaning or cleaning of the multi-component material exit the mixing chamber so that the cleaned material is atomized and in the direction of the objects is sent out in such a way that the purged

4098U / CU21

234S630

Material does not deteriorate the finish on your item.

The invention is explained below with reference to the drawing, for example.

Fig. 1 is a side view of a device according to the invention, partly in section and in which parts are shown in broken lines.

; Fig. 2 is an enlarged cross-sectional view partially showing the rotatable portion and opening of the Pig device. i shows the chamber and opening in the mixing and material sending partition. 3 is an enlarged cross-sectional view of the chamber and opening of the apparatus of FIG. 1, showing the chamber and opening in the material removal and cleaning layer, respectively.
Figure h is a perspective isometric view of an automatic electrostatic spray coating system embodying the concept of the present invention.

FIG. 5 shows an enlarged top plan view, partially in section, of the spray device shown in FIG Fig. 4 is shown.

In FIGS. 1 to 3, a hand spray gun according to the invention is provided with the reference numeral 10. The hand gun comprises a main gun body portion 11, a handle 12 protruding from the body at an angle thereto, and a trigger or trigger 13 on. The body 11, the handle 12 and the trigger 13 as well as other purposes— moderately intended parts of the pistol 10 are made of any corrosion or wear resistant material, which in relation to the components to be mixed and the multicomponent material, which from the to

4098 1-4 / 0421

mixing components results, is chemically inert. Appropriate materials include aluminum, aluminum alloys, Steel, steel alloys, copper alloys, plastics, e.g. acetal resin, epoxy resin, glass-filled epoxy, nylon, and glass-filled nylon.

A first component, component A, and a second component, component B, of a multi-component material flow into inlet openings 16 and 17, respectively, which are in the sides of the gun body 11, as in FIG shown are arranged. The inlet openings 16 and 17 are made of suitable materials, the opposite components A and B are chemically inert. For example, steel, steel alloys, ceramics and plastics be used. A line 14 connects the gun to a container 18, for example the Component A contains. A line 15 connects the gun 10 with a container 19, for example the component B contains.

The multicomponent material sprayed from the gun can be any one that has been catalyzed Be multi-component material that atomizes into particles which has a spray point size of approximately 0.38 mm (15 mils) or less and which can be air dried to give a dried Form a film that is easy to handle within about 30 minutes. For the purpose of explanation a suitable multi-component material provided with a catalyst is a two-component polyurethane-resin system, which has a prepolymer or an addition product which has free isocyanate groups, the useful or useful films in combination with a catalyst, an accelerator or a crosslinking agent, for example monomeric polyol or polyamine. The container 18 contains the component A, which is an appropriate Isocyanate end group polymer, and the container

409814/0421

includes component B, which is an appropriate poly ■ functional reactive amine or polyol. The treatment or curing of polyurethane. Is carried out Mixing the prepolymer with polyfunctional reactive Amines and polyols brought about.

A hose 20 supplies compressed air or other gas from a source 21 to the spray gun 10 through an appropriate one Regulating valve (not shown) by connecting the hose 20 with a coupling 22. A slidable one On-off valve 23 controls the supply of compressed air to the gun 10. Compressed air is used to control the mixed To atomize component material emitted from the gun 10, and to spray the oyster produced by the gun is sent out to shape. Furthermore, the Compressed air used to remove the gun 10 from essentially all of the remainder of ingredients A and B upon termination to clean their inflow to the gun.

As shown in Figure 1, the trigger 13 is of a suitable length and is pivotally connected to the gun. The trigger 13 is pivotally connected to the pistol about an axis formed by a bolt 2k which is used to mount the trigger on the pistol.

Pivotal displacement of the trigger 13 in the direction of the handle 12 causes the trigger to engage and depress a valve plunger 25, which in turn an air valve 26 is actuated. The actuated air valve 26 allows air to pass through to the anterior chamber Air operated device 27, which is arranged at the rear end of the main body 11 of the gun 10, flows. the air operated device 27 has a double acting piston 28, the piston rod 29 within the hollow end of a rotary cylinder 30 slidably received is. The connection of a pin 30a fixed in the cylinder 30 with a helical groove 22a in rod 29 forms the axial movement of the piston rod

4098U / 0A21

in the rotary motion of the rotary cylinder 30 about its axis by »

The increased air pressure acts against the piston 28, causes that the piston rod 29 moves backwards, and this in turn causes the cylinder 30 to rotate out of its normal position. Moved accordingly itself when compressed air to the rear chamber of the through air actuated device 27 by releasing the trigger 13 is fed, the piston rod forward to accordingly to rotate the cylinder 30 in the opposite direction "

A flange on the foremost end of the cylinder 30 is received in a slot on the rear part of the rotatable part 35. The part 35 has a mixing chamber in it 36 and is provided with an opening 37. Of the rotatable portion 35 'shown in the drawings has an outer surface 35a which acts as a surface of rotation around the Axis of the chamber 36 is formed, and it can consist of any appropriate material, for example a steel alloy, be made. Rotation of the cylinder 30 causes a corresponding rotation of the part 35 and accordingly rotation of the mixing chamber 36 and the opening 37 »Die Rotation of the part 35 enables the ingredients or components A and B to be fed into the mixing chamber 36 the openings 38 and 39. It will be noted that the opening 37 not to the front, to the back or to the side in relation to each other on the front face of the gun 10 while still following the rotation of the part 35. This is significant in order to achieve the required atomization of the pulling material at all times.

In the gun 10, the opening 37 is for the flowable Material in cooperative relationship with compressed air atomizer 40 through bearing surfaces 40 a and 42a of the gun body. The outer surface 35a of part 35 (Pig x 2 and 3) has a spherical or spherical and a cylindrical surface of revolution. A print

4098 U / 0 42 1

Bearing 31 presses the part 35 through the cylinder 30 front. The outer surface 35a is accordingly kept in contact with the bearing surface 41a of the gun body, which comes into conformance with this and the Movement of the part 35 is limited along its axis of rotation. The bearing surface 4ia has a portion 41b, which has high sliding properties in order to reduce friction and to increase the freedom of rotation of the part 35. The bearing surface 42a joins the cylindrical outer surface of the Part 35 in conformal engagement, which is arranged adjacent to the opening 37 for the flowable material and the Movement of the part 35 in the lateral direction with respect to the openings 45 and 46 of the compressed air atomization device 40 limited. Grooves 35b in the outer surface 35a of the Part 35 allow air to sweep past bearing surface 42a.

The rotatable part 35 is within the body in the Gun 10 arranged. The part 35 has an opening 37 from which the material is sent out, the mixing chamber 36, in which the mixing of components A and B is brought about, and further a plurality of inlet openings or openings 38 and 39 which are connected to the mixing chamber 36 are connected and either with the containers 18 and 19 of the components A and B of the Mehrlcomp onent enmat erials or connected to the compressed air source 21, as shown in FIG. 3 can be used to clean the mixing chamber.

In the drawing, the cross-sectional dimensions of the mixing chamber 36 and the opening 37 are shown round, and the Cross-sectional dimensions of the mixing chamber and the opening are shown as being substantially the same. It can be very be good that under certain working conditions, the opening 37 has a diameter or cross-sectional structure which differs from the diameter or cross-sectional structure of FIG Chamber 36 is different.

The component A is into the mixing chamber 36 through the

4098U / 0421

Port 38 and inlet port 16 inserted; Which a suitable test valve, as shown in Fig. 2, has. The component 3 is passed into the mixing chamber 36 the opening 39 and the inlet opening 17, which are arranged at an angular distance of approximately 180 ° from the inlet opening 16 is introduced. It goes without saying that a plurality of small openings for each of the large openings 38 and 39 can be used. The introduction of components A and B in a tangential direction with respect to the mixing chamber 36 appears to result in turbulence sufficient for proper mixing and action to bring about the constituents on each other. It should be understood, however, that openings 38 and 39 define the mixing chamber 36 can cut in the direction of the seam and to the rear be arranged from the opening 37 at unequal distances as long as proper mixing and acting of the ingredients is accomplished.

The front end parts kl and k2 form the front end of the pistol 10, close off the front part of the main gun body 11 and also create bearing surfaces in order to bring the part 35t into position or to hold it in position as described above. The front end parts kl and k2 are suitably attached to the body so as to be screw-engaged with the body, and they may be made of the same material as that of the main body 11. The front end parts kl and k2 have an inner surface which, together with the outer surface of the front section of the part 35 », create an air passage kj to the front part of the pistol 10.

An air cap kk has a pair of. Compressed air- emitting _{openings k5 t} which are arranged on oppositely arranged projections, and one or more air-emitting openings k6 which surround the opening 37 for the flowable material. The air cap is mounted kk kk to the gun body 10 provides a threaded retainer ring provided. Air openings k6 direct compressed air in

4098U / CU21

Direction of the Mehrkomp onent eninat er ial exiting from the opening 37 so as to atomize the emitted material into particles having a particle size such as to achieve a quality finish on the object, preferably with a spray point size of approximately 0.38 mia (15 mil) or less. Furthermore, the compressed air emanating from the openings 45 is used to transform the atomized particles into an elliptical or fan-shaped spray luster. A suitable line pressure in hose 20 for the air used to atomize the multicomponent material discharged from port 37 is in the range of about 3.5 to about 7.1 kp / cm ² (50 to 100 psi).

In Figs. 1 and 3, the trigger 13 is in its non- spraying position or ileinigungslage shown and the openings 38 and 39 are arranged so that components A and B cannot enter the mixing chamber 36. The openings 38 and 39 of part 35 are now through an air chamber 48 located in the body 11 at the rear end of the part 35 is formed, with the compressed air source 21 in connection. Cleaning or blow-off air under appropriate pressure, which is supplied through the hose 20, flows out of the air chamber 48, through the openings 38 and 39 and out the opening 37 out. This position of the openings is best in Pig. 3 to see.

With the foregoing in mind, the following describes the operation with reference to the drawings the multicomponent spray gun 10 reproduced.

An operator presses the trigger 13, air flows to the front chamber of the air operated device 27, pulls the piston 28 back and thereby rotates the part 35 and its mixing chamber 36. The part 35 which the Mixing chamber 36 is moved from its cleaning position, as shown in FIG. 3, to its spray position, as in FIG. 2 shown twisted. The openings 38 and 39 are now with

40981 4/0421

the delivery lines 14 and 15 for the flowable components essentially in alignment. The components A and B are dzw in the Mischkaruiier 36 through openings 38. 39 introduced in the tangential direction. A rapidly swirling amount of material becomes inside the mixing chamber 36 formed so that components A and B are carefully mixed will. Compressed air flowing out of the openings of the air cap 44 enters with the A component mixture and B, which are discharged from the opening 37, interact to make the mixture into particles with a spray. spot size of approximately 0.38 mm (15 mils) or less atomize, and around the atomized component material particles to shape. Air is supplied through air cap 44 from source 21 through passages 43 and 49.

The interruption of the porting of the spraying process is brought about by the fact that the trigger 13 returns to its normal or cleaning position in a pivoting motion, in that the operator releases the pressure exerted on the trigger 13. The release of the trigger causes the piston 28 to move forward, thereby rotating the part 35 with its openings 38 and 39, its chamber 36 and the opening 37. The openings 38 and 39 are displaceably separated from the lines 14 and 15 or are not aligned with them and are thereby separated from the corresponding component containers IS and 19. As the part 35 moves, the openings 38 and 39 move until they are completely exposed to the compressed air chamber 48. A substantial portion of the air flowing from the source 21 is now led out of the chamber 48 through the opening 38 and 39, the chamber 36 and the opening 37, whereby the openings are cleaned, the mixing chamber and the opening of all remainder of the component material is cleaned and dangerous sticking of the spray gun is prevented.

Movement of part 35 to the cleaning position

A098U / 0A2.1

does not stop the flow of compressed air from the openings in any pall in air cap 44, as best seen in FIG. This is an important feature as it ensures that the cleaned-off residue as well as the multicomponent material from the opening 37 during normal Spraying process is dispensed, atomized in .Teilchen in the desired spray point size of approximately 0.38 mia (15 mil) and is deposited or deposited on the object without destroying its coating or finish.

If the gun 10 is not to be used for an extended period of time, an on-off valve 23 should be placed in the Exhibition moved to flow the compressed air to the gun to quit.

Venn also the compressed air gun 10, which is shown in FIGS 1-3 of the drawings is a hand-held or hand-operated pistol, the invention can can also be implemented in a corresponding manner in a remote-controlled or automatic pistol. Furthermore, Although the spray gun 10 is not an electrostatic gun, the invention can also apply to an electrostatic one Gun to be applied. Figs. 4 and 5 show an automatic electrostatic spray coating system in which the concept of the invention is embodied.

In Figs. 4 and 5, the automatic electrostatic gun is designated by the reference numeral 50. the Gun has a gun body 5i and a support flange 52 protruding from the body. Gun 50 is on attached to a stand 53. The gun body 5i and the Flanges 52 are made of any suitable material, such as that shown in the embodiment Material an aluminum alloy. The stand 53 is in its upper part 53a made of an electrically insulating material, for example nylon.

The structure of the pistol 50 and its connections to the Compressed air and the coating components are essentially

40981 4/0421

lichen corresponding to the pistol 10, as described above, with the exception of four differences. First, the gun body 51 is by means of a high voltage cable 5- ^ t connected to an Iloch voltage source 55, so that the gun and all conductive parts connected to the gun are on the desired High voltage, which is in the range of 30 to 120 kV.

! Second, a needle-shaped metal electrode 56 is fastened axially to the mixing chamber 57 in the rotatable part 58. The electrode 56 protrudes from the rear end of the chamber 56, out of the opening for the liquid and ends about 12.5 kim (1/2 inch) from the opening.

Third, the front end of the gun 50 is included an insulating material covered in which the air cap 59 and the retaining ring 60 made of an insulating material made, for example, glass-filled nylon. Accordingly, except for the front surface of the part 58, which surrounds the opening for the flowable material and the electrode 56, all parts of the front region of FIG Gun 50 exposed to the atmosphere made of insulating material.

Fourth, the gun 50 is remote instead of manual actuated, i.e. switched on and switched off. Accordingly, the rotation of the member 58 is increased by their connection a remote controlled double acting air cylinder 61 or by other known remote controlled devices brought about

The gun 50, which is attached to the insulating stand 53, is spaced approximately 30 cm (12 inches) from the metal objects 62 which are to be spray coated and which are suspended by hangers 63 from a conveyor 6k . The objects are grounded by the conveyor device 64. The gun is connected to the cable 50 and to the high-voltage

409814/0421

source 55 is held at a high potential. Accordingly a high electrostatic field is applied to the end of electrode 56 to aid in charging and deposition of the flowable particles sprayed from the gun 50 as disclosed in U.S. Patent 3,169,882. With the exception of electrostatic charging and Deposition process works the coating system shown in Fig. 4 essentially like the system described above and shown in Pig, 1-3.

Accordingly, the invention includes electrostatic and non-electrostatic compressed air spray guns with a part for mixing the components of a multi-component material, which is movably attached to the gun body. An actuation part, which is either a trigger or a compressed air cylinder, is the mixing chamber into a spray layer in which the components flow into an inner mixing chamber and through aligned Openings in the part with facilities to hold the components to the outer surface of the part through which the inner mixing chamber can flow. The parts are accordingly mixed automatically and by actuation of the actuating part sprayed.

The mixing chamber is automatically turned back into a non-spray position by a biasing device, for example a spring in the air cylinder, when the actuating part is de-energized, for example when the trigger of the hand gun is released. In this second position, the stroia of the ingredients is blocked from their respective delivery means by the outer surface of the mixing chamber, the openings of which are then placed in communication with means in the gun body for supplying pressurized air to the orifices, thus terminating the spraying and simultaneous termination To carry out cleaning or cleaning of the openings, the chamber and the opening for the flowable material.

A098U / 0421

The movement of the mixer "does not move the Opening for the flowable material in the longitudinal direction along its axis or in the lateral direction in reference on the compressed air atomizer, and accordingly becomes their interacting relationship during spraying and cleaning the gun. In the guns shown, the mixing chamber has an outer surface known as Rotary surface is formed. The outer surface of rotation is reduced their diameter in the longitudinal direction along their axis of rotation just like the illustrated spherical part 35 * The gun body conforms to this outer surface engaged to create a bearing surface allowing movement of the opening for the liquid to come out of its co-operating Position with the compressed air atomizing device on the front End of the fistole body prevented.

The following examples of spray coating a The subject matter is also to explain the invention given. It will be understood that substrates, other than metal, can be oversprayed when using the process and the device according to the invention can be used. Such other substrates include wood, hardboard, epoxy, fiberglass reinforced polyester, among others and masonry with or without a primary coating, but are not limited to these.

example 1

A steel metal surface that is to be coated is clean, tight and free of dust, wax, grease, oil, rust and other foreign material. The metal surface is preferred sandblown, and all of the remainder of the sandblown dust is made with toluene or a vapor degreaser removed.

Component A is a blend of materials manufactured by the Sherwin-Willams Co. of Cleveland, Ohio will. Approximately 300 parts by volume of resin sold under the name Polane and ID number 179825 (i6)

4098U / CK21

234663Q

asks, with about 117 parts by volume of a reduc- by means of mixed, which bears the identification number R7K69. the Component B is unmixed and not reduced Catalyst V66V28, which is made by the above company on sale is. The components come with the gun IO a flow rate of component A of 417 cciu / iain and 50 ccu / niin of component B supplied. The management— The pressure for component Λ is approximately 4.9 kp / cm (70 psi) and the line pressure for component 'B is approximately 4.2 kp / cm "(60 psi). Line pressure is approximately 6.4 kgf / cm (90 psi) µm a spray point size of less than 0.38 ium (15 mils) reach. The gun 10 is positioned about 25 to about 37 cm (10 to 15 inches) from the substrate during the outside spraying and atomization of the material held. The passage or a step of the pistol is approximately overlapped. After about 30 minutes the surface of the polyurethane film is sufficiently dried to allow easy handling. After curing the film overnight, it is essentially hard. Of the film produced has a thickness of approximately 0.03 ebb (l mil), appears to be essentially continuous and has a strength or toughness, an abrasion resistance, impact resistance, chemical resistance, and Resistance to solvents as required for high quality finishes.

Of course, the time to create a hard film can be reduced to 30 minutes, by exposing the film to an elevated temperature of approximately 82 ° C (180 ° F).

Example 2

A steel metal surface that is to be sprayed over, is clean and free from dust, wax, grease, oil, rust and other foreign material. The metal surface is preferred sandblown, and all of the remainder of the sandblown dust is made with toluene or a vapor degreaser removed.

4Q98U / 0421

The component A is a mixture of materials which is produced by the aforementioned company. Approximately 600 parts by volume of Ilarz, which is sold under the name Polane and has the identification number 179825 (i6), is mixed in container 18 with approximately 206 parts of the reducer with the Kennumuier R7K69. Component B is a mixture of approximately 500 parts by volume of the catalyst V66V27 and approximately ΙΛΟ parts by volume of the reducing agent Π7ΚΤ39, both of which are sold by the company named above. The components are introduced into the gun 10 with a component A flow rate of approximately 403 cc / min and kit a component B flow rate of approximately 64 cc / min. The line pressure for component A and for component. B, and the line pressure for the atomizing air line have the same values as mentioned above. The gun 10 is held a distance of about 25 to about 37 cm (10-15 inches) from the substrate while the material is being dispensed and atomized. The passage or step of the gun is approximately halfway overlapped. After about 30 minutes, the surface of the polyurethane film is essentially dry to allow easy handling. After curing the film overnight, it is essentially hard. The resulting film is substantially uniform with a thickness of about 0.03 mm (1 mil) and has toughness, abrasion resistance, impact resistance, chemical resistance, and solvent resistance as required for a quality finish.

4098U / CU21

Claims (13)

© Claims
A method of forming a thin, solid, homogeneous coating on the surface of an object comprising the step of delivering the flowable component A to a mixing chamber within a compressed air atomizing gun; delivering component B to the mixing chamber; mixing components A and B within the chamber; emitting the mixture of ingredients A and B from the gun as a stream of flowable material; atomizing the stream of flowable material into a spray mist or the like of finely divided flowable particles by the action of compressed air which is output from the gun; settling the sprayed material of flowable particles substantially uniformly on the surface of the article; converting the deposited flowable jet into a solid, homogeneous coating having a substantially uniform thickness of not less than 0.03 mm (1 mil) and not more than about 0.05 mm (2 mil) in thickness, the energy for the conversion by the reaction of components A and B with each other, and ceasing the supply of components A and B to the mixing chamber and simultaneously blowing off the chamber of the flowable components by a stream of pressurized air passing through the chamber. 2. A method of spraying flowable material which includes the steps of: introducing two Components of the material to be sprayed into a movable mixing chamber; mixing the components in the chamber; sending the mixed material out from an opening in the chamber; directing compressed air to the material dispensed from the opening, including transforming the dispensed material into a spray of the material, and moving the chamber to introduce the 4098U / 04 21 Components in the Cairo without changing the location of the Complete the opening, thereby spraying the material without destroying the quality of the sprayed material. 3. Process for spraying flowable material, which comprises the steps of: introducing two components of the material to be sprayed into a mixing chamber; Mixing the components in the chamber; Directing compressed air onto the material dispensed from the opening in order to convert the dispensed material into a spray mist; "Separate feeding the ingredients into the chamber without to change the position of the opening in order to spray the material without destroying the quality of what is sprayed and immediately following the switching off of the supply of the components into the chamber, blow off or Cleaning the remainder of the components from the chamber by means of a pressurized air stream passing through the chamber. h » Method according to claim 3, characterized by electrostatic charging of the spray material. 5 · Device for spraying a multi-component material, with a gun body; a first and a second Means to mix the gun body, with separate sources of the first and second components and to be sprayed from the gun to connect; means to supply the gun body with a source of compressed air connect to; a device for directing a jet of compressed air out of the gun body and with a discharge opening for the multi-component material which is connected to the first and to the second device, and cooperating with respect to the means for directing the compressed air stream out of the gun body is arranged to a spray mist or the like. The multi-component material to create, characterized by a mixing device for the first and the second component in the Connection between the first and the second device 4Q98 U / 0421 BATH of the body and the emitting opening; through a facility for connecting the compressed air source to the mixing chamber; by a mixing device attached to the gun body from a first position in which the first and the second component pass through the mixing device to the discharge opening can flow therethrough to a second position in which the flow of the first and second components "is blocked and a compressed air stream through the mixing device and the discharge opening can flow, movably is attached, the mixing device on the body is movably mounted in such a way that its movement does not enter either the discharge opening for the mixed components Longitudinal direction along its axis still in the lateral direction with respect to the device zuia guiding or calibrating the Moved compressed air flow, and by an actuator for moving the mixing device between the first and the second position. 6. Spray device according to claim 1, characterized in that the device for sending out the compressed air— Stromes formed from the gun body made of insulating material and the mixing device is an elongated needle pen Electrode around which the components are mixed and which is in position with respect to the opening for the flowable material and the device for emitting the compressed air flow from the gun, is arranged, to load the spray of multicomponent material. 7. Spray device for a multi-component coating material, especially spray gun, with a combined valve, chamber and opening for flowable A material consisting of a part having an outer surface shaped about an axis as a surface of revolution; one inner mixing chamber in which the first and second mixing flowable components of the coating material; two openings between the inner chamber and the outer surface and one opening for flowable AQ98U / CK21 Material at the front of the spray gun communicating with the interior chamber from which the mixed components are dispensed, characterized in that the spray gun body includes means for delivering the first flowable component, the second flowable component to be mixed and added and the pressurized air for cleaning and souring the inner chamber from separate sources to the outer surface; the spray gun body has pressurized air atomizing means at its forward end which is operatively connected to the flowable material opening of the gun body; the part that comes into engagement with the spray nozzle on its outer surface creates two working positions which are arranged separately in angular denominations about the axis of the outer surface, a spray position in which the two openings of the part with the delivery device for the first and second flowable components in alignment with the outer surface and in which at the same time the outer surface of the part blocks the compressed air supply means, and a non-spray position in which the two openings are in alignment with the means for supplying compressed air to the outer surface and in which at the same time the outer surface blocks the means for delivering the first and second flowable components, and that an actuating member is provided to rotate the part about its axis of its outer surface to simultaneously mix and spray the coating material in the spray position and simultaneously terminate the Mixing and spraying of the coating material and the cleaning and cleaning of the openings, the chamber and the opening for flowable material in the non-spray position. 8. Spray device according to claim 7 »characterized in that that the outer surface of rotation of the part in longitudinal 40 98 U / 0-421 direction decreases along its axis of rotation and that the spray gun body conformingly engages the outer surface of the part to create a bearing surface that Movement of the orifice for flowable material in the longitudinal direction along its axis and in the lateral direction in with respect to the compressed air atomizing device on the front part of the spray gun body. 9. Spray device according to one of claims 7 or 8, characterized in that the outer rotating surface of the Part a spherical part on v / ice and the spray- gun body has a spherical portion that engages the outer surface of the rotating member. 10. Spray device for a micro-component material n with a gun body; a device for forming a Mixing chamber within the gun body for mixing the constituents of the material immediately before they come out of the Gun issued; wherein the device is movably mounted within the pistol and within the pistol with the components of the material to be mixed and the Compressed air source is connectable; an opening for flowable Material communicating with the chamber for sending the mixed material out of the gun and with a compressed air device passing through the gun body carried for atomizing the material emitted from the opening into a spray of flowable material and having means for automatically moving the chamber from a position in which the components are introduced into the mixing chamber, in a position in which the supply of the components into the chamber is completed and pressurized air is introduced into the chamber to purge and clean it without opening the chamber flowable material from the interacting relationship with the compressed air device to thereby remove the mixed material discharged from the gun during the Cleaning is cleaned to atomize. 4098U / CU21 11. Spray device according to claim 10, characterized in that that the device is to atomize the material in a spray a plurality of openings on v / eist the compressed air in such a way send out the flowable sprayed material to one shape elliptical spray pattern. 12. Spray device according to claim 10, characterized in that that the device for forming a mixing chamber is rotatable and has an outer surface of rotation and that the gun body has a long surface on v / eist, which with the outer surface of the mixing chamber device in conformal Is engaged to the opening for flowable material in cooperative relationship with the compressed air means to keep. 13. Spray device according to claim 10, characterized in that the means for forming the mixing chamber Has openings which are connectable to the components of the material to be mixed when they are in the are a position, and which are connectable to the compressed air source for cleaning from the chamber when they are are in the second position. lh. A spray device according to claim Ik , characterized in that the gun body "has a handle and a trigger in the vicinity of the handle to move the device forming a mixing chamber, the device for automatically moving the chamber receiving energy from the actuation of the Trigger stores to be used when the trigger is released to "stop spraying" and to supply compressed air to the mixing chamber and the flowable material opening to clean them. 4098 1 4 / CU21 Le first page